Novel treatment of severe combined immunodeficiency utilizing ex-vivo T-cell depleted haploidentical hematopoietic stem cell transplantation and CD45RA+ depleted donor lymphocyte infusions

R E S E A R C H

Open Access

Novel treatment of severe combined

immunodeficiency utilizing

ex-vivo

T-cell

depleted haploidentical hematopoietic

stem cell transplantation and CD45RA+

depleted donor lymphocyte infusions

Nicholas Brodszki

, Dominik Turkiewicz

, Jacek Toporski

, Lennart Truedsson

and Josefina Dykes

Abstract

Background:Allogeneic hematopoietic stem cell transplantation (HSCT) is the only curative treatment available for severe combined immunodeficiency (SCID); although, there is a high incidence of severe infections and an increased risk of graft-versus host-disease (GvHD) with HSCT. Early intervention is a crucial prognostic factor and a HLA-haploidentical parental donor is often available. Haploidentical HSCT protocols utilizing extensivelyex vivoT-cell depleted grafts (CliniMACs system) have proven efficient in preventing GvHD, but cause a delay in early T-cell recovery that increases the risk of viral infections. Here, we present a novel approach for treating SCID that combines selective depletion of GvHD-inducing alpha/beta (α/β) T-cells from the haploidentical HSCT graft with a subsequent donor lymphocyte infusion (DLI) enriched for CD45RO+ memory T-cells.

Results:Our patient was diagnosed with SCID (T-B + NK+ phenotype). At 9 months of age, he received a T cell receptor(TCR)α/β-cell depleted graft from his haploidentical mother, following a reduced intensity conditioning regimen with no additional GvHD prophylaxis. Engraftment was rapid with complete donor chimerism and no signs of GvHD. However, at 12 weeks post HSCT, the patient was still T-cell lymphopenic with clinical symptoms of multiple severe viral infections. Consequently, therapeutic DLIs were initiated for enhanced anti-viral immunity. The patient was treated with CD45RA+ depleted haploidentical maternal donor lymphocytes enriched from unmobilized whole blood, and a total T-cell dose of no more than 25 x103CD3+ cells/kg with >99.9 % purity of CD3 + CD45RO+ memory T-cells was transferred. Following the DLI, a prompt increase in CD3 + CD4+ and CD3 + CD8+ counts was observed with a subsequent clearance of viral infections. No acute or chronic GvHD was observed.

Conclusions:Automated depletion of CD45RA+ naïve T-cells from unmobilized whole blood is a simple and rapid strategy to provide unmanipulated DLIs, with a potentially broad repertoire of pathogen specific memory T-cells. In the haploidentical setting, CD45RA+ depleted DLIs can be safely administered at low T-cell doses for efficient enhancement of viral immunity and limited risk of GvHD. We demonstrate the successful use of this approach following TCR-α/β-cell depleted HSCT for the treatment of SCID.

Keywords:Pediatric, Immunodeficiency, Hematopoietic stem cell transplantation, Lymphocytes, Donor lymphocyte infusion, Haploidentical, T cell depletion

* Correspondence:Nicholas.Brodszki@skane.se

1_{Children’s Hospital, Skåne University Hospital, Lund, Sweden}

Full list of author information is available at the end of the article

Background

Severe combined immunodeficiency (SCID) is a rare disorder defined by a profound developmental or functional defect of T lymphocytes. If unrecognized, it can cause death during the first years of life, due to the life-threatening increased susceptibility to infections [1] therefore early detection and treatment of SCID, be-fore infections become overwhelming, optimizes survival [2–4]. Today, most forms of SCID are treated with hematopoietic stem cell transplantation (HSCT) and if HSCT is not successful and genetic treatment is not an option, the alternatives are few [5].

For patients lacking a human leukocyte antigen (HLA)-matched sibling or unrelated stem cell donor or when there is an urgent need for a HSCT, an HLA-haploidentical par-ental donor is often readily available [6]. Given the major HLA donor-recipient disparities in the haploidentical set-ting, measures are required to prevent the occurrence of alloreactive responses, i.e. graft rejection or severe graft-versus host-disease (GvHD). The extensive ex-vivo deple-tion of donor T-cells (CliniMACS system) has proven effi-cient in preventing GvHD [6, 7], but is inevitably coupled to a delay in early T-cell recovery and, thus, to an increased risk of viral infections [6–9]. Recent efforts to balance the risk of GvHD against that of delayed immune reconstitution include the selective depletion of GvHD-inducing alpha/beta (α/β) T-cells while retaining poten-tially beneficial gamma/delta (γ/δ) T-cells in the haploi-dentical graft [10, 11].

Unselected donor lymphocyte infusions (DLIs), which are frequently used as a“tool”to boost anti-viral immun-ity post-transplant, harbor a significant risk of inducing severe GvHD in the haploidentical setting [6, 7]. GvHD-inducing cells reside mainly in the CD45RA+ naïve T-cell population whereas viral-specific memory T-cells are pre-dominantly CD45RA-negative [12]. Thus, the depletion of CD45RA+ T cells from DLIs may provide a potentially broad repertoire of donor-derived viral-immunity with a limited risk of GvHD [13, 14].

Herein, we report on the successful treatment of SCID by combining T cell receptor (TCR)-α/β-cell depleted haploidentical HSCT with CD45RA+ depleted DLI for an antiviral boost.

Methods Patient

The male patient was born at full term, after a normal pregnancy, as the third child of Afghanistani related par-ents. Both parents and the siblings are healthy. He had his first upper respiratory tract infection (URTI) at the age of 2 weeks and at the age of 1 month, he was admitted for the first time to a pediatric ward for 2 weeks with cough-ing, low grade fever and hoarseness. In the following 3 months, he was followed regularly due to coughing,

hoarseness and failure to thrive. At the age of 4 months, he was infected with chicken-pox. Three weeks after the onset of the infection, new blisters were still forming and varicella keratitis developed. The unusually severe course of the infection and the failure to thrive warranted investi-gation for primary immunodeficiency disorder (PID), in conformity with our protocol [15].

Investigations

Routine blood investigations during his first 4 months of life showed normal leukocyte and neutrophil counts on several occasions. Total lymphocytes were measured dur-ing the first admission at 1 month of age, but the low value of 0.6 (ref: 3–8.4 × 109/L) was attributed to an upper respiratory tract infection (URTI) and was followed up only at the beginning of the chicken-pox infection when the level was 6.2x109/L. Other laboratory tests, including electrolytes, ALT, AST, GT, pancreatic amylase, bilirubin, organic acids, amino acids, and the thyroid hormone sta-tus, were normal. At the time point of PID investigation, he was anemic (hemoglobin: 81 g/L) with normal platelets and a total lymphocyte count of 2.2x109/L. The immuno-logical investigation revealed very low T-cell counts, confirming a T-B + NK+ SCID phenotype. The cultures taken at this point showed multiple infections: positive

Staphylococcus aureus blood culture, cytomegalovirus (CMV), and varicella virus DNA positivity in blood, vari-cella DNA in the cerebrospinal fluid,Pneumocystis jiroveci and coronavirus NL63 on throat swabs, rotavirus in feces, and high serum beta-d-glucan.

Genetic analysis

Genomic DNA was prepared from blood collected in EDTA, fragmented to an average length of 300 bp, and exome enriched using the SureSelect XT Human All Exon v5 technology (Agilent). Sequencing was carried out to an average coverage of 150-fold using PE 2x100 bp sequencing (Illumina HiSeq 2500). The bioinformatic analysis was carried out using the Mutation Identifica-tion Pipeline (MIP) [16]. Results were presented in an interactive browser-based visualization tool (Scout), de-veloped in-house (Science for Life Laboratory, Solna, Sweden). The clinical interpretation of the results was restricted to a predefined set of 233 genes known to be involved in primary immunodeficiencies.

(Val131Phe) in the CD3G gene, was identified, but it received a low rank score due to its reported high fre-quency of 0.21 in the 1000 Genomes database and was, therefore, considered a natural variant. Thus, no known genetic defect was identified.

Donor selection

Considering the low numbers of lymphocytes and the life-threatening infections, the decision was made to per-form a HSCT. The parents provided written inper-formed consent for this procedure. No HLA matched siblings were available and the probability of finding a matched unrelated donor was considered low given the patient´s ethnical origin. Consequently, the choice was made to select a HLA-haploidentical parental donor. The patient and his parents were investigated according to our insti-tutional protocol for haploidentical HSCT, including high resolution allelic typing for HLA- A*, -B*, -C,* DRB1*, DQB1*, BPB1* (PCR-sequence specific primers [SSP], Olerup SSP AB), HLA-donor specific antibodies (DSA) (LabScreen Singel Antigen, Luminex platform, One Lambda, Thermo Fisher), ABO-blood grouping and CMV-serology. The mother was selected as the donor based on the outcome of the pre-transplant investigation, and this selection was further supported by the reported higher survival rate in haploidentical HSCT patients grafted from the mother compared with recipients of paternal grafts [17]. The HLA-typing confirmed patient and donor haploidentity with a DRB1*, DQB1*, and DPB1* allelic match in the host-versus-graft direction. No DSA were detected in the patient´s serum. The patient and the donor were matched for ABO-blood group and were both CMV positive.

Transplant protocol

The patient was conditioned with a myeloablative regimen, according to guidelines [18] regarding HSCT for primary immunodeficiencies with a haploidentical family donor in patients older than 3 months. How-ever, due to his very poor health status, we decided to use a reduced intensity regimen conditioning. This consisted of i.v. anti-thymoglobuline (ATG Fresenius ®) given from day -9 to -6 (first day 1 mg/kg bodyweight and then 10 mg/kg bodyweight), fludarabine (40 mg/m2/day, from day -7 to -4), thiotepa (5 mg/kg twice a day; day -3), and melfalan (70 mg/m2day -2 to -1). The sole form of GvHD prevention was the immunomagnetic depletion of TCR-α/β+ cells from the graft. Prophylaxis against post-transplant Epstein–Barr virus-associated lymphoprolif-erative disease (EBV-PTLD) consisted of one dose of rituximab (375 mg/m2) given at day +1. No post-transplantation pharmacological immunosuppression was used.

Graft engineering

Peripheral blood progenitor cells (PBPCs) of the haploi-dentical maternal donor were mobilized by granulocyte-colony-stimulating factor (G-CSF, 10 μg/kg/day) and collected by leukapheresis (Cobe Spectra, Terumo BCT) on day 4 of G-CSF administration. Collected PBPCs were processed under clean room conditions with the Clini-MACS system (Miltenyi Biotech), according to the manu-facturer´s protocol. The cells were sequentially labelled with TCR-α/β-Biotin reagent and CliniMACS anti-Biotin reagent, and processed with the CliniMACS device using the D3.1 program with the Depletion Tubing Set (DTS). The graft cell contents were determined by flow cytometric analysis (FACS, Canto II, Becton Dickinson [BD]), using antibodies against CD45, CD34, CD14, CD19, CD56, CD3, TCR-α/βand TCR-γ/δ with 7-AAD as a viability marker (BD). According to our institutional protocol for haploi-dentical HSCTs, the target cell dose of the TCR-α/β-cell depleted graft was set to >10 × 106CD34+ cells/kg (mini-mum 5 × 106CD34+/kg) and <25 × 103TCR-α/β+ cells/kg (maximum 1 × 105TCR -α/β+ /kg).

Manufacturing of donor lymphocytes

A bag of unmobilized whole blood was drawn from the donor. Utilizing a closed blood bag system, whole blood was separated by density centrifugation to obtain a leukocyte enriched cell fraction for further processing with the CliniMACS system. According to the manufac-turer´s protocol, cells were labelled with CD45RA re-agent and processed under clean room conditions with the CliniMACS device using the D3.1 program with the DTS. The cell contents of the CD45RA-depleted target fraction was assessed by FACS (Canto II, BD), using antibodies against CD3, CD4, CD8, CD45RO, and CD45RA with 7-AAD as a viability marker (BD).

Post-treatment evaluation

Engraftment following HSCT was monitored by daily counts of leukocytes, neutrophils, and platelets. Immune recovery was assessed post HSCT and after DLI by FACS (Canto II, BD) of peripheral blood lymphocytes, using anti-bodies against CD3, CD4, CD8, CD19, CD56, TCR-α/β, TCR-γ/δ, CD45RA and CD45RO (BD). Donor myeloid and T-cell chimerism was monitored by DNA genotyping of short tandem repeat polymorphisms (PCR-STR, 3500 Dx Genetic Analyzer, Applied Biosystems). The patient was evaluated for signs of acute and chronic GvHD.

Compliance with ethical guidelines

patient’s parents was sufficient for publication of this case and the consent was obtained.

Results

Collection, depletion, and recovery

A single leukapheresis procedure provided 31 × 106 CD34+ cells/kg recipient weight for subsequent

TCR-α/β-cell depletion with the CliniMACS system. The log10TCR-α/β-cell depletion rate was -5.0,

correspond-ing to 0.005 % TCR-α/β+ cells in the target fraction. The recovery of CD34+ cells and TCR-γ/δ+ cells was 99 %. Cell viability post-sorting was 98 %. The TCR-α/

β-depleted graft contained per kg of recipient weight 30.8 × 106 CD34+ cells, 0.11 × 105 TCR-α/β+ cells, 29.7 × 106 TCR-γ/δ+ cells, 237.7 × 106 CD19+ B-cells and 162.2 × 106 CD56+ NK-cells and was transplanted in total to the patient. The donor had antibodies against CMV, VZV EBV and herpes simplex.

Engraftment and immunological reconstitution

Hematological recovery post HSCT was prompt with a white blood cell count >1 × 109/L at day +10, neutro-phils >0.5 × 109/L at day +12, and thrombocytes >50 × 109/L at day +13. Complete myeloid and T-cell donor chimerism was reached at day +19. As expected (16), NK-cells co-infused with the graft expanded rapidly, with normal peripheral counts from day + 14 (ref: 0.13– 0.72 × 109/L). However, despite the prompt three-linear hematological recovery, the patient remained pro-foundly T-cell lymphopenic (Fig. 1). ATG clearance vary between individuals and the efficacy of ATG varies between batches [19, 20]; therefore an explanation of the lymphopenia could be that since we used ATG in a relatively high dose, given timewise quite close to the grafting, this affected the graft, hence could be consid-ered as additional in vivo T-cell depletion. Due to the persistent effect of rituximab, B-cell recovery was also markedly delayed.

Donor lymphocyte infusions

A single unit of donor whole blood provided a surplus of CD3+ cells (62.2 × 106/kg recipient weight) for subsequent CD45RA+ depletion using the CliniMACS system.

The log10CD3 + CD45RA+ cell depletion rate was -3.8,

corresponding to 0.0049 % residual CD3 + CD45RA+ cells in the target fraction. The recovery of CD3 + CD45RO+ cells was 51 %. Cell viability post-sorting was 96 %. The tar-get fraction contained 12.6 × 106 CD4 + CD45RO+ cells and 1.3 × 106 CD8 + CD45RO+ cells per kg of recipient weight, with an increased CD4+/CD8+ ratio compared with the starting product (9.6 versus 2.1). Aliquots of CD45RA+ depleted products containing 25 × 103 CD3+ cells/kg of recipient weight were prepared for fresh DLI and cryopreservation. The patient received a fresh

CD45RA+ depleted DLI of 25 × 103 CD3+ cells/kg from the original HSCT donor at day +84 post HSCT. At the time of DLI (day +84 post HSCT), peripheral blood CD3 + CD4+ and CD3 + CD8+ levels were <10 × 106 /L, but reached 178 × 106 /L and 111 × 106/L, respectively, at 22 days following DLI. At 57 days after DLI, all T-lymphocyte subset counts were normalized (Fig. 1), corresponding to a continuously complete donor T-cell chimerism. The circulating T-cells were predominantly CD4 + CD45RA+ (935 × 106 /L) and CD8 + CD45RA+ (586 × 106/L).

Post-transplant morbidity

The patient did not experience any acute GvHD after HSCT or DLI. The early post-transplant period was complicated at day +5 by acute mechanical ileus with unknown etiology. This was resolved by mechanical ma-nipulation during the exploratory laparotomy. The blood tests showed continued VZV positivity and the numbers of CMV copies were increasing. His condition deterio-rated further and he suffered an Enterococcus faecium septicemia at day +74, followed by severe diarrhea and gastrointestinal tract bleeding, signs of probable colitis. The stool analysis revealed CMV, in addition to rota-virus. Two weeks after DLI, the test results showed that the CMV was resistant to ganciclovir; therefore, the anti-viral treatment was changed to foscarnet. Following DLI, the time to clearance of VZV and rotavirus was 22 days. The CMV levels decreased rapidly (Fig. 2) and the pa-tient’s condition improved considerably. The stool analysis for CMV was negative at 15 days following DLI and cleared from peripheral blood at 73 days. Supplementation with immunoglobulins was discontinued on day +99 post HSCT. He was discharged approximately 6 months post HSCT. No chronic GvHD was observed after the HSCT or DLI. He developed blindness and one-sided micro-phthalmia due to the varicella keratitis. At 21 months after HSCT, the patient had a normal lymphocyte count with normal lymphocyte subsets and neither new nor were exacerbations of preexisting infections observed.

Discussion

we present a novel approach for treating SCID, com-bining TCR-α/β-cell depleted haploidentical HSCT with CD45RA+ depleted DLI for a therapeutic anti-viral boost.

Our patient received a TCR-α/β-cell depleted graft from his haploidentical mother, following a reduced

intensity conditioning regimen with a short course of ATG, a single dose of rituximab to prevent EBV-PTLD, and no additional GvHD prophylaxis. Engraftment was rapid with complete donor chimerism and no signs of GvHD. However, at 12 weeks post HSCT, the patient was still T-cell lymphopenic with clinical symptoms of

Fig. 1Total lymphocyte count (TLC) and concentrations of different lymphocyte subsets (indicated by CD positivity) over time in relation to

multiple severe viral infections. Consequently, the deci-sion was made to initiate therapeutic DLIs for enhanced anti-viral immunity.

In the haploidentical setting, unselected DLIs with a T-cell add-back of only 25 × 103 CD3+ cells/kg may cause severe GvHD [6, 7]. In contrast, enriched CD3 + CD45RO + memory T-cells may provide viral immunity with mark-edly reduced alloreactivity [13, 14]. Notwithstanding, cross-reactivity of memory viral-specific T-cells with mis-matched HLA has been described and is, thus, a potential source of GvHD in haploidentical HSCT [27]. Based on these observations, the patient was treated with CD45RA+ depleted haploidentical donor lymphocytes, transferring a total T-cell dose of no more than 25 × 103CD3+ cells/kg with >99.9 % purity of CD3+ CD45RO+ memory T-cells. Following DLI, a prompt increase in CD3 + CD4+ and CD3 + CD8+ counts was observed, with a concomitant reduction in viral load and a subsequent clearance of viral infections. No acute or chronic GvHD was observed. As previously demonstrated [28], TCR-α/β cells could be efficiently depleted (log -5.0) with the CliniMACS instru-ment, preserving high numbers of CD34+ cells and

potentially beneficial TCR-gd + cells and NK-cells in the graft. With the current approach of transferring a very low dose of CD45RA+ depleted donor T-cells (25 × 103/kg CD3+ cells), a sample of donor peripheral blood will pro-vide sufficient numbers of lymphocytes.

To ensure that the manufacturing of DLIs was in com-pliance with Good Manufacturing Process (GMP) condi-tions, a closed blood bag system was used for the collection and leukocyte enrichment of donor whole blood and the CliniMACS instrument was used for sub-sequent CD45RA+ depletion. Naïve T-cells (CD45RA+) were efficiently depleted (log -3.8) providing sufficient numbers of CD3 + CD45RO+ cells for the fresh DLI and for cryopreservation. A benefit of the current protocol is the time and cost effectiveness of using a whole blood donation rather than a leukapheresis product as starting material. Moreover, this approach is also less strenuous for the donor.

A long-standing approach to control refractory viral in-fections following HSCT is the generation of antigen-specific T-cells against single pathogens such as CMV, adenovirus, or EBV [29]. New strategies have been

developed forex vivoselection of pathogen-specific donor T-cells, using antigen induced stimulation and isolation by cytokine secretion assay [24] or HLA-peptide streptamers [25]. However, this approach is time consuming and tech-nically much more demanding than the simple method of cell depletion based on surface CD45RA+ antigen expres-sion. Also, the generation of antigen stimulated T-cells for clinical application is subjected to a more complex regula-tory framework than that of CD45RA+ depleted, unma-nipulated lymphocytes. Recently, the often limited therapeutic effect of using antigen-specific T-cells has been attributed to the limited in vivo persistence of trans-ferred donor T-cells [29], suggesting that adoptive transfer should include a variety of donor T-cell populations to favor long-lasting clinical responses.

Very recently, three different groups [21, 22, 23] investi-gated the use of CD45RA+ depletion as part of the haploi-dentical or HLA-mismatched donor graft processing. Using different conditioning regimens with different stem cell sources and graft compositions, with or without ser-otherapy, two of the groups [21, 23] reported limited or no GvHD despite high numbers of transferred CD3 + CD45RO+ T-cells (1-100 x 106/kg) while the third group reported a 17.6 % incidence of grade III/IV acute GvHD. Further studies are required to determine the optimal tim-ing, T-cell dose, and source of CD45RA+ depleted donor lymphocytes - as part of the graft or as prophylactic, pre-emptive, or therapeutic DLIs.

Conclusion

Automated depletion of CD45RA+ naïve T-cells from unmobilized whole blood donations is a simple and rapid strategy to provide unmanipulated DLIs, with a potentially broad repertoire of pathogen specific memory T-cells. In the haploidentical setting, therapeutic CD45RA+ depleted DLIs can be safely administered at low T-cell doses for efficient enhancement of viral immunity and limited risk of GvHD. We demonstrate the success of this approach following TCR-α/β-cell depleted HSCT for the treatment of SCID.

Abbreviations

CMV:Cytomegalovirus; DLI: Donor lymphocyte infusion; DSA: HLA-donor specific antibodies; EBV-PTLD: Epstein_–Barr virus-associated lymphoproliferative disease; GvHD: Graft-versus host-disease; HLA: Human leukocyte antigen; HSCT: Hematopoietic stem cell transplantation; MIP: Mutation Identification Pipeline; PBPCs: Peripheral blood progenitor cells; PID: Primary

immunodeficiency disorder; SCID: Severe combined immunodeficiency; TCR: T cell receptor; URTI: Upper respiratory tract infection; VZV: varicella zoster virus.

Competing interests

The authors declare that they have no competing interests.

Authors’contributions

NB: conception and planning, collection and compiling of the clinical and laboratory data, and writing the manuscript. DT, JT, and LT: interpretation of the results and supervising the writing of the manuscript. JD: collection and

compiling of the laboratory data and supervising the writing of the manuscript. All authors read and approved the final manuscript.

Acknowledgements

The design of this project did not need any special funding and the authors would like to thank the Medical Faculty of Lund University and Skåne University Hospital for the opportunity to carry out this project. The authors would like to thank the patient and his family for their kind collaboration in this project, as well as their doctors.

Author details

1_{Children’s Hospital, Skåne University Hospital, Lund, Sweden.}2_Department

of Laboratory Medicine, Section of Microbiology, Immunology and Glycobiology, Lund University, Lund, Sweden.3_{Department of Laboratory}

Medicine, Section of Haematology and Transfusion Medicine, Lund University, Lund, Sweden.

Received: 9 November 2015 Accepted: 10 January 2016

References

1. van der Burg M, Gennery AR. Educational paper. The expanding clinical and immunological spectrum of severe combined immunodeficiency. Eur J Pediatr. 2011;170(5):561–71.

2. Brown L, Xu-Bayford J, Allwood Z, Slatter M, Cant A, Davies EG, et al. Neonatal diagnosis of severe combined immunodeficiency leads to significantly improved survival outcome: the case for newborn screening. Blood. 2011;117(11):3243–6.

3. Dvorak CC, Cowan MJ, Logan BR, Notarangelo LD, Griffith LM, Puck JM, et al. The natural history of children with severe combined immunodeficiency: baseline features of the first fifty patients of the primary immune deficiency treatment consortium prospective study 6901. J Clin Immunol. 2013;33(7): 1156–64.

4. Pai SY, Logan BR, Griffith LM, Buckley RH, Parrott RE, Dvorak CC, et al. Transplantation outcomes for severe combined immunodeficiency, 2000-2009. N Engl J Med. 2014;371(5):434_–46.

5. Gaspar HB, Qasim W, Davies EG, Rao K, Amrolia PJ, Veys P. How I treat severe combined immunodeficiency. Blood. 2013;122(23):3749–58. 6. Handgretinger R, Klingebiel T, Lang P, Schumm M, Neu S, Geiselhart A, et al.

Megadose transplantation of purified peripheral blood CD34(+) progenitor cells from HLA-mismatched parental donors in children. Bone Marrow Transplant. 2001;27(8):777–83.

7. Klingebiel T, Handgretinger R, Lang P, Bader P, Niethammer D. Haploidentical transplantation for acute lymphoblastic leukemia in childhood. Blood Rev. 2004;18(3):181_–92.

8. Lang P, Greil J, Bader P, Handgretinger R, Klingebiel T, Schumm M, et al. Long-term outcome after haploidentical stem cell transplantation in children. Blood Cells Mol Dis. 2004;33(3):281_–7.

9. Lang P, Teltschik HM, Feuchtinger T, Muller I, Pfeiffer M, Schumm M, et al. Transplantation of CD3/CD19 depleted allografts from haploidentical family donors in paediatric leukaemia. Br J Haematol. 2014;165(5):688–98. 10. Bertaina A, Merli P, Rutella S, Pagliara D, Bernardo ME, Masetti R, et al.

HLA-haploidentical stem cell transplantation after removal of alphabeta + T and B cells in children with nonmalignant disorders. Blood. 2014;124(5):822–6. 11. Lang P, Feuchtinger T, Teltschik HM, Schwinger W, Schlegel P, Pfeiffer M,

et al. Improved immune recovery after transplantation of TCRalphabeta/ CD19-depleted allografts from haploidentical donors in pediatric patients. Bone Marrow Transplant. 2015;50 Suppl 2:S6–10.

12. Mahnke YD, Brodie TM, Sallusto F, Roederer M, Lugli E. The who's who of T-cell differentiation: human memory T-cell subsets. Eur J Immunol. 2013;43(11): 2797–809.

13. Bleakley M, Heimfeld S, Jones LA, Turtle C, Krause D, Riddell SR, et al. Engineering human peripheral blood stem cell grafts that are depleted of naive T cells and retain functional pathogen-specific memory T cells. Biol Blood Marrow Transplant. 2014;20(5):705–16.

15. Brodszki N, Jonsson G, Skattum L, Truedsson L. Primary immunodeficiency in infection-prone children in southern Sweden: occurrence, clinical characteristics and immunological findings. BMC Immunol. 2014;15(1):31. 16. Stranneheim H, Engvall M, Naess K, Lesko N, Larsson P, Dahlberg M, et al.

Rapid pulsed whole genome sequencing for comprehensive acute diagnostics of inborn errors of metabolism. BMC Genomics. 2014;15:1090. 17. Stern M, Ruggeri L, Mancusi A, Bernardo ME, de Angelis C, Bucher C, et al. Survival after T cell-depleted haploidentical stem cell transplantation is improved using the mother as donor. Blood. 2008;112(7):2990–5. 18. ESID/EBMT. EBMT/ESID guidelines for haematopoietic stem cell

transplantation for primary immunodeficiencies. 2011.

19. Oevermann L, Lang P, Feuchtinger T, Schumm M, Teltschik HM, Schlegel P, et al. Immune reconstitution and strategies for rebuilding the immune system after haploidentical stem cell transplantation. Ann N Y Acad Sci. 2012;1266:161–70.

20. Podgorny PJ, Ugarte-Torres A, Liu Y, Williamson TS, Russell JA, Storek J. High rabbit-antihuman thymocyte globulin levels are associated with low likelihood of graft-vs-host disease and high likelihood of posttransplant

lymphoproliferative disorder. Biol Blood Marrow Transplant. 2010;16(7):915–26. 21. Shook DR, Triplett BM, Eldridge PW, Kang G, Srinivasan A, Leung W.

Haploidentical stem cell transplantation augmented by CD45RA negative lymphocytes provides rapid engraftment and excellent tolerability. Pediatr Blood Cancer. 2015;62(4):666–73.

22. Triplett BM, Shook DR, Eldridge P, Li Y, Kang G, Dallas M, et al. Rapid memory T-cell reconstitution recapitulating CD45RA-depleted haploidentical transplant graft content in patients with hematologic malignancies. Bone Marrow Transplant. 2015;50(7):1012.

23. Touzot F, Neven B, Dal-Cortivo L, Gabrion A, Moshous D, Cros G et al. CD45RA depletion in HLA-mismatched allogeneic hematopoietic stem cell transplantation for primary combined immunodeficiency: A preliminary study. J Allergy Clin Immunol. 2015;135(5):1303-9 e1-3.

24. Feuchtinger T, Opherk K, Bethge WA, Topp MS, Schuster FR, Weissinger EM, et al. Adoptive transfer of pp 65-specific T cells for the treatment of chemorefractory cytomegalovirus disease or reactivation after haploidentical and matched unrelated stem cell transplantation. Blood. 2010;116(20):4360–7. 25. Schmitt A, Tonn T, Busch DH, Grigoleit GU, Einsele H, Odendahl M, et al.

Adoptive transfer and selective reconstitution of streptamer-selected cytomegalovirus-specific CD8+ T cells leads to virus clearance in patients after allogeneic peripheral blood stem cell transplantation. Transfusion. 2011;51(3):591–9.

26. Martelli MF, Di Ianni M, Ruggeri L, Falzetti F, Carotti A, Terenzi A, et al. HLA-haploidentical transplantation with regulatory and conventional T-cell adoptive immunotherapy prevents acute leukemia relapse. Blood. 2014;124(4):638–44. 27. Melenhorst JJ, Scheinberg P, Williams A, Ambrozak DR, Keyvanfar K, Smith M, et al. Alloreactivity across HLA barriers is mediated by both naive and antigen-experienced T cells. Biol Blood Marrow Transplant. 2011;17(6):800_–9. 28. Dykes JH HA, Toporski J, Lenhoff S, Scheding S, Turkiewicz D. Effective TcR

α/β+ cell depletion using the CliniMACS® system to produce peripheral blood progenitor cell products for haploidentical transplantation. Bone Marrow Transplant. 2013;48:S72_–458.

29. Einsele H, Loffler J, Kapp M, Rasche L, Mielke S, Grigoleit UG.

Immunotherapy for viral and fungal infections. Bone Marrow Transplant. 2015;50 Suppl 2:S51–4.

• We accept pre-submission inquiries

• Our selector tool helps you to find the most relevant journal • We provide round the clock customer support

• Convenient online submission • Thorough peer review

• Inclusion in PubMed and all major indexing services • Maximum visibility for your research

Submit your manuscript at www.biomedcentral.com/submit